Excluded Volume Effects in Polymer Solutions. 1. Dilute Solution

1. Dilute Solution Properties of Linear Chains in Good and ϑ Solvents ... All data beyond the oligomeric range collapsed to a master curve for each p...
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Macromolecules 1999, 32, 3502-3509

Excluded Volume Effects in Polymer Solutions. 1. Dilute Solution Properties of Linear Chains in Good and Θ Solvents Ryan C. Hayward and William W. Graessley*,† Department of Chemical Engineering, Princeton University, Princeton, New Jersey 08544 Received December 11, 1998; Revised Manuscript Received March 15, 1999

ABSTRACT: Data from the literature on four dilute solution propertiessradius of gyration, second virial coefficient, intrinsic viscosity, and diffusion coefficientswere analyzed for linear flexible-chain polymers of several species in both thermodynamically good solvents and Θ solvents. Each property was expressed as an effective coil radius, and the ratio of good to Θ solvent radius, the excluded volume expansion factor, was examined over a wide range of chain lengths. The expansion factor, near unity for short chains, crosses over to a power law dependence on chain length for long chains. All data beyond the oligomeric range collapsed to a master curve for each property by a simple rescaling of the chain lengths. The crossovers for these curves are more abrupt than those predicted by the classical theories of polymer solutions. The excluded volume per monomeric unit, obtained by matching experiment and prediction in the power law region, is generally much smaller than the hard sphere prediction in even the best of good solvents. These observations are examined in the light of numerical simulations in the following paper.

Introduction The dilute solution properties of flexible-chain polymers have been studied for many years. Early investigations were based on viscometric, osmometric, sedimentation, and light scattering intensity measurements. Those techniques were later supplemented by dynamic light scattering and by small-angle neutron and X-ray scattering. Nearly monodisperse samples were used in most studies, supplied at first by fractionation procedures and later by anionic polymerization. The combination of these experiments with theories based on the random-coil model has led to a rather good understanding of the solvent-mediated intramolecular interactions in the dilute regime, excluded volume, and hydrodynamic coupling.1-6 A longtime goal, pursued most recently in a series of investigations by Yamakawa, Einaga, and co-workers, is the detailed description of behavior over the full range of sizes. They employ the helical wormlike chain (HWC) model to describe the properties of chains in the small to intermediate size range.7 Their work has had the additional benefit of making available an extensive new body of high-quality data for linear chains of several species, filling out what had been a rather sparse collection of results in the smaller size range. In this paper, we combine the Yamakawa-Einaga data with earlier results in order to investigate the apparent weakness of excluded volume effects in even the best of good solvent systems.8 We focus on the behavior of flexible chain species in good solvents only. Data for short chains are included, but the interpretation emphasizes intermediate and long chains, and it omits any detailed consideration of HWC effects. We also do not consider excluded volume effects in the region near the Θ condition or polymer species with large persistence lengths. The effects of excluded volume on various dilute solution properties are expressed, insofar as possible, ‡ Current address: 7496 Old Channel Trail, Montague, MI 49437.

in the form of master curves that contain the particularities of species in the reducing parameters alone. Molecular interpretation is deferred until the validity of this approach, a generalized form of the twoparameter theory of dilute polymer solutions,7 is established. A similar approach is used in the following paper9 to organize the results of Monte Carlo simulations for self-avoiding chains with varying strengths of self-attraction. Four dilute-solution properties are consideredsradius of gyration Rg, second virial coefficient A2, intrinsic viscosity [η], and diffusion coefficient Do. The first two are equilibrium properties, the other two are dynamical. Each property varies with chain length, as represented here by the molecular weight M, and each depends on the solution thermodynamics. To facilitate comparison among effects on the various properties, we have expressed each as a molecular size. The radius of gyration is of course already a size, and the others are converted to effective sizes by means of expressions for hard sphere solutes10

Rt ) Rv )

(

)

3 A2M2 16π Na

(

1/3

)

(2)

kBT 6πηsDo

(3)

3 [η]M 10π Na

Rh )

(1) 1/3

in which Rt, Rv, and Rh are the thermodynamic, viscometric, and hydrodynamic radii, Na is Avogadro’s number, kB is Boltzmann’s constant, T is the temperature, and ηs is the solvent viscosity. Excluded volume at the binary interaction level is canceled at the Θ condition, so (Rt)Θ ) 0. For longenough chains the other sizes vary with chain length in the random-walk manner:

10.1021/ma981914x CCC: $18.00 © 1999 American Chemical Society Published on Web 04/21/1999

Macromolecules, Vol. 32, No. 10, 1999

Excluded Volume Effects 3503

(Rg)Θ ) KsM1/2

(4)

(Rv)Θ ) KvM1/2

(5)

(Rh)Θ ) KhM1/2

(6)

The expansion of molecular size in good solvents caused by volume exclusion is quantified by an expansion factor denoted by R. Thus,

Rs ) Rv )

Rv (Rv)Θ Rh )

Rg

(7)

(Rg)Θ )

( ) [η] [η]Θ

Rh (Rh)Θ

1/3

(8) (9)

For uniformity of discussion we have included the available data for A2 in the expansion factor formalism but, since (Rt)Θ ) 0, doing that requires a different method for normalizing the good solvent values. Davidson et al.10 noted that ratios of radii such as Rh/Rv and Rh/Rg have values in the long-chain region that are relatively insensitive to chain length and to the solution thermodynamics as well. We use that observation to construct an Rt normalization size from (Rg)Θ and a value for Rt/Rg in good solvents. The values of Rt/Rg are similar for the three good solvent systems discussed in ref 10. The average, 0.676, is used to define the Rt normalization size, 0.676(Rg)Θ, and from that a thermodynamic expansion factor:

Rt )

Rt 0.676(Rg)Θ

Figure 1. Relationship between radius of gyration and molecular weight for polystyrene in cyclohexane at Θ (b) and in toluene (0). The dashed line indicates the best fit to limiting behavior at Θ, given in Table 2.

(10)

Data obtained from the literature sources listed in Table 1 are considered for eight polymer species: polystyrene [PS], poly(R-methylstyrene) [PRMS], atactic poly(methyl methacrylate) [aPMMA], isotactic poly(methyl methacrylate) [iPMMA], polyisobutylene [PIB], poly(dimethylsiloxane) [PDMS], 1,4-polybutadiene [PBD], and 1,4-polyisoprene [PI]. (The last two are statistical copolymers of 1,4-cis and 1,4-trans units, and they also contain ∼8% 1,2 or 3,4 units. The isomeric proportions vary insignificantly with chain length for the samples studied, so PBD and PI are homopolymers in the context of this study.) All samples are linear and have narrow molecular weight distributions. Their molecular weights were determined by a variety of absolute techniques, although a scattering method giving Mw was most commonly used. Since the distributions are narrow, the type of averaging is relatively unimportant, so we have dropped the subscript and are simply using M to designate the molecular weight. Some of the references include compilations of earlier data.23,37 In particular, ref 23 contains extensive data from the Fujita laboratory44-49 and the studies of Burchard and co-workers.50,51 We have omitted results published prior to 1965. Our search was not exhaustive, and some good data may have been overlooked, particularly in the case of polystyrene, which has been studied carefully by many groups. Analysis of Data Properties in good solvents and at the Θ condition were examined for each species over the widest possible

Figure 2. Relationship between intrinsic viscosity and molecular weight for polystyrene in cyclohexane at Θ (b) and in toluene (0). The dotted line indicates the best fit to limiting behavior at Θ, given in Table 2.

range of chain lengths. Preliminary examination of the data indicated significant differences in the coil size for individual samples among the various good solvents, so the behavior in each good solvent system was analyzed separately. Data were available in only one Θ solvent for most species. For PS, however, results in four Θ solvents were availablescyclohexane (for which there is the most data), trans-decalin, Decalin (a mixture of cis and trans isomers), and dioctyl phthalate. Results in two Θ solvents, benzene and isoamyl isovalerate, were available for PIB. Also, different researchers using the same Θ solvent for a given species sometimes report slightly different values of the Θ temperature. In nearly all cases, however, close agreement was found between the data from different investigators, even when different values of the Θ temperature, or different Θ solvents, were used. The only exception was PDMS, for which the results in two Θ solvents, methyl ethyl ketone and bromocyclohexane, disagreed significantly. We chose to disregard the methyl ethyl ketone data since the results in bromocyclohexane are more extensive. Behavior that is typical of all the polymer species is illustrated in Figures 1 and 2, which show Rg and [η] as functions of M for PS in cyclohexane (Θ condition) and toluene (good solvent). As illustrated in these figures and well-known for many years, Θ condition values of both Rg and [η] are characterized throughout the intermediate- and long-chain region by a linear

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Macromolecules, Vol. 32, No. 10, 1999 Table 1. Sources of Data Used in the Study refs

solvent

Rg

cyclohexanea decalin trans-decalin dioctyl-phthalate benzene toluene ethylbenzene dichloroethane 4-tert-butyltoluene n-butyl chloride tetrahydrofuran acetonitrile n-butyl chloride nitroethane chloroform acetone acetonitrile nitroethane chloroform acetone

[η]

11, 12, 23 21 20, 21, 23 11, 12, 18, 20, 23 23 20 18 18 23

bromocyclohexane methylethyl ketone toluene cyclohexane

16

23

23

A2

17, 23 19 23 16, 23 23

25 25 25

aPMMA 25, 27 25, 27 25 25 25

29

26, 28

iPMMA 30

29, 30

24, 25

28 28

isoamyl isovalerate benzene cyclohexane n-heptaneb

D0

PS 13, 14, 21, 22, 23 11 21 11 13, 15, 20, 21, 22, 23 11, 14, 20, 23 23 20 16

28 28

32, 33, 36 33, 36 12, 33, 36, 37, 38

PDMS 39, 41 39, 41 40, 41 41

19, 41 40, 41

1,4-dioxane cyclohexane tetrahydrofuran

23 23

1,4-dioxane cyclohexane

23, 43 23

cyclohexane toluene

23 23

29 31 31 31

32 32 32

29

PIB 12, 33, 34, 35, 36 33, 35 33, 36 12, 33, 34, 36

20, 21, 23 11, 18, 20, 23 23 20 18 18 23

34, 36 36 34, 36

33, 36 33, 36

39 40

41

23 23

23, 42

PI 23, 43 23

23 23

23

P(RMS) 23 23

23 23

PBD 23 23, 42 42

23

uses a variety of Θ solvents, including cyclohexane and several mixtures of decalin isomers. Values of Rg at low molecular weights37 were measured in n-decane. a

Berry11

b

Table 2. Coefficients for Dilute Solution Relationships at the Θ Condition polymer

(Rg/M1/2)Θ (nm)

([η]/M1/2)Θ (cm3/g)

(Rh/M1/2 )Θ (nm)

PS PRMS aPMMA iPMMA PDMS PIB PI PBD

0.028 0.028 0.025 0.030 0.0295 0.031 0.0333 0.0377

0.085 0.074 0.055 0.093 0.083 0.11 0.13 0.18

0.022 0.021 0.020 0.0235 0.022 0.024 0.026 0.028

dependence on M1/2. This was found to be the case for (Rg)Θ, (Rh)Θ, and [η]Θ for all the species. Coefficients relating each of the unperturbed properties to its asymptotic M1/2 form are given in Table 2. They were determined by visual fits of the data because the judgment required to locate the onset of asymptotic behavior made it difficult to apply least-squares fitting. In the short-chain region, values in good solvents and Θ solvents are nearly the same, as exemplified in

Figures 1 and 2, although each may deviate from the M1/2 behavior. This deviation reflects a species-dependent breakdown of the random coil model in the short chain region and, for the dynamic properties, of variations in hydrodynamic penetration as well.7 Interesting oddities such as negative intrinsic viscosities appear in this range (PIB and PDMS). At somewhat higher molecular weights the Θ solvent data begin to display the aforementioned M1/2 dependence, but with good solvent values the same or only slightly larger than the corresponding to Θ solvent values. Finally, beyond a certain molecular weight range, which depends on both the property and the polymer-solvent system, sizes in the good solvents begin to depart significantly from the Θ solvent sizes, with the good solvent sizes eventually taking on their limiting power-law dependence on chain length. Values of the expansion factor were obtained somewhat differently in the short-chain and long-chain regions. Considerable amounts of data for long chains in good solvents were available on samples for which

Macromolecules, Vol. 32, No. 10, 1999

Excluded Volume Effects 3505

Figure 3. Expansion factor vs molecular weight for polyisobutylene in good solvents n-heptane (]) and cyclohexane (0): (a) Rs; (b) Rt; (c) Rv; (d) Rh.

no corresponding to Θ solvent measurement had been made. To make use of these data and yet treat all results uniformly, expansion factors for the medium- to longchain region were calculated by the long-chain method, i.e., by applying eqs 7-10 to the observed good solvent size and to a Θ solvent size calculated with the molecular weight and the appropriate equation from Table 2. For example, the size expansion factor was calculated as

Rs )

Rg KsM1/2

(11)

with Ks for each species taken from Table 2. Equations 4-6 do not accurately describe short-chain behavior in Θ solvents, as Figures 1 and 2 demonstrate. In this region, expansion factors were calculated by the short-chain methodsby applying eqs 7-9, but using only values measured in both Θ and good solvents for the same sample. The short-chain method was used wherever possible, so, as shown in subsequent figures, there is considerable overlap of results from the two methods. We have no basis for applying eq 10 to short chains, so Rt was not evaluated in this region. Figure 3 illustrates some characteristics of the expansion factors for long chains with data for PIB in two good solvents, n-heptane and cyclohexane. The results are typical of those found in the other polymer-solvent systems. Thus, the relationship between Rx and M (x ) s, t, v, h) varies from one polymer species to another and, for a given species, from one good solvent to another. However, the forms of each of these relationships are similar: the data for different polymersolvent systems can be superimposed by a simple rescaling of the molecular weight, i.e., by translation of

Table 3. Limiting Power-Law Exponents for the Expansion Factors expansion factor

exponent

Rs Rt Rv Rh

0.092 ( 0.003 0.088 ( 0.002 0.079 ( 0.001 0.077 ( 0.006

log Rx vs log M plots parallel to the log M axis. Superposition was the most convincing and produced the least scatter for Rt and Rv. The somewhat larger spread of values encountered with Rs and Rh was due to scatter in the data for the individual polymer-solvent systems and not to poor superposition of otherwise welldefined curves. For each of the four expansion factors, the results for one polymer-solvent system with well-defined behavior over a wide range of molecular weights was used as a reference, and results for the other systems were shifted to coincide with that reference curve. Once satisfactory superposition had been achieved, as judged visually, a least-squares regression was performed to obtain a power-law fit for the long-chain region. The limiting exponents so obtained for each propertysps, pt, pv, and phsare given in Table 3. To remove the dependence of the best-fit equations on an arbitrary reference system, the molecular weights for each polymer-solvent pair were normalized by a scale factor denoted as M‡, which corresponds to the intersection of the limiting power law with R ) 1. Thus, in the long chain region, the expansion factors for each polymer-solvent system are expressed as

Rs )

( ) M M‡x

px

(M . M‡x)

(12)

3506 Hayward and Graessley

Macromolecules, Vol. 32, No. 10, 1999

Figure 4. Expansion factors vs reduced molecular weight, evaluated in the short-chain method (b) and the long-chain method (]): (a) Rs; (b) Rt; (c) Rv; (d) Rh. Table 4. Characteristic Molecular Weights for Various Polymer-Solvent Systemsa polymer PS

solvent

M ‡s

M‡ t

benzene 4800 3880 toluene (6420) (4200) dichloroethane 12000 8090 ethylbenzene (8280) 7600 tetrahydrofuran (7660) 2590 PRMS toluene (12400) 8090 aPMMA acetone 19900 19700 nitroethane 4430 3070 chloroform 950 420 benzene iPMMA acetone 50490 129000 nitroethane 10700 chloroform 2070 1680 PDMS toluene 13000 cyclohexane PIB n-heptane 27700 29800 cyclohexane 5790 2940 PI cyclohexane (2690) 3400 PBD cyclohexane 10300 5500 tetrahydrofuran

M ‡v

M ‡h

8070 12800 14800 19500 10800 16800 33000 6730 1010 3700 87400

(14000) (13200)

(M‡)av

7700 9200 11600 (30300) 16400 (4920) 6500 (19300) 14200 24200 4700 790 3700 89000 10700 2820 2200 18000 17800 16300 7740 7700 33000 30300 30200 5180 3220 4300 3770 3480 3400 5720 8700 7600 4700 4700

a Values in parentheses are somewhat less certain than the others.

For each polymer-solvent system, M‡x is a crossover molecular weight (x ) s, t, v, h) that specifies the range where significant departures from the Θ-condition size begin. Values of M‡x obtained for the various properties, species, and good solvents are given in Table 4. Plots of Rx vs M/M‡x for both long- and short-chain data are shown in Figure 4. In the overlap region there is good agreement between data analyzed in the shortchain and long-chain methods. The transition near M‡x is a relatively abrupt one. That is, at molecular weights below M‡x, the expansion factors quickly approach and then scatter around unity, while not far above M‡x the

behavior is already well described by the power law. Note, however, that our method of forming the master curves and assigning the values of M‡x relies almost entirely on the long-chain data. Accordingly, any features reflecting species-dependent behavior in the shortchain region, and hence unlikely to scale with M/M‡x, would be obscured. Discussion Expansion Factor Parameters. The four limiting power-law exponents (Table 3) do not differ greatly from one another. Within the uncertainties, those for the equilibrium properties, ps and pt, are indistinguishable. The same is true for the dynamic-property exponents, pv and ph. Indeed, whatever differences there might be between the chain-length dependence of Rt and Rg is lost in the data scatter, as shown by the plot of Rt/Rg vs M/M‡ in Figure 5. The average for M > M‡, Rt/Rg ) 0.668 ( 0.005, is essentially the same as reported by Davidson et al.10 and is in excellent accord with Rt/Rg ) 0.690 from Monte Carlo simulations of self-avoiding walks.52 The chain-length dependence of the dynamic sizes is similarly indistinguishable, as shown by the plot of Rv/Rh in Figure 6. The average for M > M‡ is Rv/Rh ) 1.073 ( 0.005 in good solvents and 1.064 ( 0.006 at Θ. Merged plots for Req (Rs and Rt) and for Rdyn (Rv and Rh) are shown as functions of M/M‡ in Figures 7 and 8. Limiting exponents for the merged plots are

peq ) 0.089 ( 0.001 pdyn ) 0.078 ( 0.001

(13)

Within the uncertainties, the value for peq agrees well with the Rs exponent from renormalization group

Macromolecules, Vol. 32, No. 10, 1999

Figure 5. Merged expansion factor for equilibrium properties vs reduced molecular weight, evaluated in the short-chain (b) and long-chain (]) manner.

Excluded Volume Effects 3507

Figure 8. Ratio of dynamic sizes vs reduced molecular weight for all species in Θ solvents (O) and good solvents (b).

to be no particular pattern in the differences. The average of all values for each polymer-solvent system, (M‡)av, is listed in Table 4. Master Curve Forms. The transition of the size expansion factor, from short-chain values near unity to the long-chain power law, is more abrupt than predicted by the commonly used theoretical forms.1,7 The crossover is quite a gradual one according to the Flory expression1

Rs5 - Rs3 ) 1.276z

(14)

in which z is the excluded volume parameter

z) Figure 6. Merged expansion factor for dynamic properties vs reduced molecular weight, evaluated in the short-chain (b) and long-chain (]) manner.

( ) 1 4π

[

theory,53 (0.5880 - 1/2) ) 0.0880, and with the exponent for both Rs and Rt from the Monte Carlo simulations,52 0.0877. The exponent for dynamic properties is discernibly smaller than for equilibrium properties. Finally, based on the experimental results in this study, the limiting exponent in good solvents for Rg is 0.5 + peq ) 0.589 ( 0.001, and that for [η] is 0.5 + 3peq ) 0.734 ( 0.004. The characteristic molecular weights for the onset of coil expansion effects (Table 4) vary somewhat erratically from one property to another. Thus, the various values of M‡x for a polymer-solvent system sometimes differ by a factor of 2 or more. In most cases M‡v and M‡h agree fairly well, and they are larger than M‡s and M‡t by an average of about 30%. Otherwise, there seems

( )

β M 3 m (Rg)Θ o

2

(15)

where mo is the molecular weight per monomeric unit, M/mo is the number of monomeric units per chain, and β is the binary cluster integral for monomeric units. The crossover is less gradual for the Domb-Barrett interpolation formula, which those authors choose to express in terms of the expansion factor for end-to-end distance:54

RR ) 1 + 10z +

Figure 7. Ratio of equilibrium sizes vs reduced molecular weight for all species in good solvents.

3/2

10 + )z (70π 9 3

2

1/15

]

+ 8π3/2 z3

(16)

It is still not as abrupt, however, as the observed behavior, as shown below. Both eqs 14 and 16 lead to the Flory power law exponent in the long-chain limit: with z ∝ M1/2 from eq 15, each has the limiting form Rs ∝ M1/10. To facilitate comparisons of crossover behavior for different properties, we force the limiting exponents to agree with the observed values (Table 3), by replacing Rs5 in eq 14 with Rs5.46 and the exponent 1/15 in eq 16 with 1/16.38, and express them in terms of M‡s through eq 12. Thus, the Flory expression becomes

Rs5.46 - Rs3 )

( ) M M‡s

1/2

(17)

in which

M‡s )

M (1.276z)2

(18)

An equation analogous to the Domb-Barrett expression (eq 16) was developed for the size expansion factor

3508 Hayward and Graessley

[

( ) M M‡s

Rs ) 1 + 2.945

1/2

Macromolecules, Vol. 32, No. 10, 1999

( ) ( )]

+ 2.449

M M + ‡ Ms M‡s

3/2 0.0611

(19)

in which

M‡s )

M 4πz2

(20)

The new equation has the observed limiting exponent ps but still preserves the correct coefficients of z and z2 in the series expansion for size.1 Equations 17 and 19 are compared with the size expansion data in Figure 9. The crossover predicted by the modified Flory expression is much too broad, as mentioned above, and the modified Domb-Barrett expression, while lying much closer to the data, is still not entirely satisfactory. The experimental results are fitted rather well by the following further modification of the Flory expression, which is shown as the solid curve in Figure 9:

Rs5.46 - Rs-20 )

( ) M M‡s

1/2

Figure 9. Expansion factor for radius of gyration vs reduced molecular weight evaluated by the short-chain method (b) and the long-chain method (]). The solid line is eq 21, the expression fitted to the data. The dashed line is eq 17, the Flory expression adjusted to fit the observed limiting dependence of Rs on M. The dotted line is eq 19, the similarly adjusted Domb-Barrett expression.

(21)

Equation 21 is now wholly empirical, having no significance beyond demonstrating that the observed crossover is abrupt enough to require what is essentially an exponential cutoff of the second term beyond M ) M‡s. We employ it merely to provide a concise and accurate description of what appears to be universal behavior for good solvents over the full range of sizes beyond the oligomeric range. A slightly different modified form fits the viscometric size ratios:

Rv6.30 - Rv-10 )

( ) M M‡v

1/2

(22)

Comparison with data and with the modified Flory form (eq 17) is shown in Figure 10. Interpretation of M‡s. Values of the binary cluster integral for monomeric units were calculated from M‡s with eqs 15 and 18:

β)

(

)

(4π)1/2 Rg M1/2

m2o

3 Θ

1.276 (Ms‡)1/2

8mo φ F Na

Table 5. Excluded Volume Parameters polymer PS

(23)

The same form is obtained by combining eqs 15 and 20, the only difference being replacement of the numerical factor 1.276 by 2π1/2 ) 3.54. The values calculated for each polymer-solvent systemswith (Rg/M1/2)Θ from Table 2, (M‡)av from Table 4, and the molecular weight of the monomeric unitsare given in Table 5. Values of (M‡)av were used instead of M‡s because of their greater reliability and availability for all systems; use of M‡s would increase the values of β by an average of 15%. The hard-sphere value of the binary cluster integral for monomeric units, βhs, was also calculated1

βhs ) 8vo )

Figure 10. Expansion factor for viscometric size vs reduced molecular weight evaluated by the short-chain method (b) and the long-chain method (]). The solid line is eq 22, the dashed line eq 17.

(24)

in which vo is the hard-core volume per monomeric unit, F is the mass density of the undiluted polymer liquid,55 and φ is the packing fraction (hard core volume)/(total liquid volume). We used an estimated packing fraction,56

PRMS aPMMA

iPMMA PDMS PIB PI PBD

solvent

β (nm3)(a)

βhs (nm3)(b)

β/βhs

benzene toluene dichloroethane ethylbenzene tetrahydrofuran toluene acetone nitroethane chloroform benzene acetone nitroethane chloroform toluene cyclohexane n-heptane cyclohexane cyclohexane cyclohexane tetrahydrofuran

0.095 0.087 0.077 0.065 0.10 0.090 0.035 0.080 0.19 0.090 0.032 0.091 0.20 0.039 0.056 0.020 0.054 0.055 0.063 0.080

0.73 0.73 0.73 0.73 0.73 0.81 0.62 0.62 0.62 0.62 0.62 0.62 0.62 0.57 0.57 0.46 0.46 0.50 0.44 0.44

0.13 0.12 0.11 0.089 0.14 0.11 0.056 0.13 0.31 0.145 0.052 0.147 0.32 0.068 0.10 0.043 0.12 0.11 0.14 0.18

φ ) 0.55, for all species. The values of βhs so obtained are listed in Table 5. The values of β in Table 5 are seen to be considerably smaller than the hard sphere value βhs. The ratio β/βhs, shown in the last column of Table 5, is about 0.1 or smaller in all systems except iPMMA and aPMMA in chloroform. Even in the best of good solvents, the chain

Macromolecules, Vol. 32, No. 10, 1999

units apparently experience a mutual attraction that is enough to offset nearly the entire hard-core repulsion. The discrepancy seems too large to be dismissed as an artifact of crudeness from the representation of polymer chains as dilute arrays of mutually excluding spheres. This is the crux of the Fujita concern about the apparently general weakness of excluded volume effects.8 On the other hand, representing the chain as a dilute array of unconnected spheres, the basis of eq 23, is certainly crude in the extreme. Strings of spheres would no doubt be preferable to unconnected arrays for modeling self-avoiding chains in dilute solution, and strings of rods with appropriately chosen diameters and lengths might be even better. It is thus conceivable that the equivalent hard-core volume, βhc, would be significantly reduced if more realistic models of flexible chains were used,59,60 making β/βhc much nearer unity. None of these physically more reasonable models has in fact been applied to the problem, however, so the discrepancy remains in principle unresolved. The numerical simulation study described in the following paper9 was undertaken in the hope of settling this quandary. Acknowledgment. We are grateful to Guy Berry, Walther Burchard, Hiroshi Fujita, and Jacques Roovers for their very helpful criticisms of an earlier version of the paper. We also gratefully acknowledge the financial support of this work provided by the National Science Foundation through a grant to Princeton University (DMR-9310762) and through an REU supplement to that grant. References and Notes (1) Yamakawa, H. Modern Theory of Polymer Solutions; Harper & Row: New York, 1971. (2) Oono, Y. Adv. Chem. Phys. 1985, 61, 301. (3) Freed, K. Renormalization Group Theory of Macromolecules; Wiley: New York, 1987. (4) des Cloizeaux, J.; Jannink, G. Polymers in Solution: Their Modelling and Structure; Clarendon Press: Oxford, England, 1990. (5) Cassassa, E. F., and Berry, G. C. In Comprehensive Polymer Science; Allen, G., Bevington, J. C., Eds.; Pengamon Press: Oxford, England, 1989; Vol. 2, Chapter 3. (6) Fujita, H. Polymer Solutions; Elsevier: Amsterdam, 1990. (7) Yamakawa, H. Helical Wormlike Chains in Polymer Solutions; Springer-Verlag: New York, 1997. (8) Fujita, H. Macromolecules 1988, 21, 179. (9) Graessley, W. W.; Hayward, R. C.; Grest, G. S. Macromolecules 1999, xxxx. (10) Davidson, N. S., Fetters, L. J., Funk, W. G., Hadjichristidis, N., Graessley, W. W. Macromolecules 1987, 20, 2614. (11) Berry, G. C. J. Chem. Phys. 1966, 44, 4550; 1967, 46, 1338. (12) Abe, F.; Einaga, Y.; Yoshizaki, T.; Yamakawa, H. Macromolecules 1993, 26, 1884. (13) Einaga, Y.; Miyaki, Y.; Fujita, H. J. Polym. Sci., Polym. Phys. Ed. 1979, 17, 2103. (14) Abe, F.; Einaga, Y.; Yamakawa, H. Macromolecules 1993, 26, 1891. (15) Einaga, Y.; Koyama, H.; Konishi, T.; Yamakawa, H. Macromolecules 1989, 22, 3419. (16) Arai, T.; Abe, F.; Yoshizaki, T.; Einaga, Y.; Yamakawa, H. Macromolecules 1995, 28, 3609. (17) Yamada, T.; Yoshizaki, T.; Yamakawa, H. Macromolecules 1992, 25, 377. (18) Yamakawa, H.; Abe, F.; Einaga, Y. Macromolecules 1993, 26, 1898. (19) Konishi, T.; Yoshizaki, T.; Yamakawa, H. Macromolecules 1991, 24, 5614. (20) Yamamoto, Y.; Fujii, M.; Tanaka, G.; Yamakawa, H. Polym. J. 1971, 2, 799. (21) Fukuda, M.; Fukutomi, M.; Kato, Y.; Hashimoto, T. J. Polym. Sci., Polym. Phys. Ed. 1974, 12, 871. (22) Altares, T., Jr.; Wyman, D. P.; Allen, V. R. J. Polym. Sci. A 1964, 2, 4533.

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